Semiconductor devices having phase change memory cells, electronic systems employing the same and methods of fabricating the same

ABSTRACT

In one embodiment, a phase-change memory device has an oxidation barrier layer to protect against memory cell contamination or oxidation and a method of manufacturing the same. In one embodiment, a semiconductor memory device comprises a molding layer overlying a semiconductor substrate. The molding layer has a protrusion portion vertically extending from a top surface thereof. The device further includes a phase-changeable material pattern adjacent the protrusion portion and a lower electrode electrically connected to the phase-changeable material pattern.

CROSS-REFERENCE TO RELATED APPLICATION

The present application is a divisional of U.S. patent application Ser. No. 11/139,283, filed May 27, 2005, now pending, which is a continuation-in-part of U.S. patent application Ser. No. 11/027,255, filed Dec. 30, 2004, issued on Aug. 12, 2008 as U.S. Pat. No. 7,411,208, which claims priority from Korean Patent Application No. 2004-37965, filed on May 27, 2004. Also, the present application claims the priority from Korean Patent Application Nos. 2004-105905 and 2005-31662, filed Dec. 14, 2004 and Apr. 15, 2005, respectively. The disclosures of all of the above applications are incorporated herein by reference in their entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates to a semiconductor memory device and methods of fabricating the same, and more particularly, to a phase-change memory device and methods of fabricating the same.

2. Description of Related Art

The use of phase-changeable materials for electronic memory applications is known in the art and is disclosed, for example, in U.S. Pat. No. 6,147,395 and U.S. Pat. No. 6,337,266. The two states of a memory, in the case of phase-changeable memory, depend on the resistance to current flow in a memory cell. The phase-changeable material typically has an amorphous phase and a crystalline phase, with inherent high and low electrical resistance, respectively. The amorphous phase exists at relatively high temperatures, and the crystalline phase exists at relatively low temperatures. Phase-changeable memory operates on the basic idea that memory cell states, i.e., “on” or “off”, are dependent on temperature. Thus, means for setting the temperature high or low is incorporated in each memory cell.

A general structure for this type of memory includes a phase-changeable material sandwiched between a lower electrode and an upper electrode. The lower electrode typically plays two roles, one being the conduction electrode to the memory cell, and the other being an ohmic heater to control the phase of the phase-changeable material. As just described, the structure comprises interfaces between the top electrode and the phase-changeable material, and between the bottom electrode and the phase-changeable material. During a fabrication of the memory device, and during its operational life in use, these interfaces may become contaminated or oxidized. Such oxidation causes a large variation in the distribution of contact resistances at these interfaces. Since the operation of phase-changeable memory depends on distinguishing between the memory cell being “on” or “off” based on the cell's resistance to current flow, contamination or oxidation jeopardizes the accuracy of memory programming. A need still remains for a novel phase-change memory structure that can prevent such contamination or oxidation and the manufacturing method thereof.

SUMMARY OF THE INVENTION

A phase-change memory device has an oxidation barrier layer to protect against memory cell contamination or oxidation and a method of manufacturing the same. In one embodiment, a semiconductor memory device comprises a molding layer overlying a semiconductor substrate. The molding layer has a protrusion portion vertically extending from a top surface thereof. The device further includes a phase-changeable material pattern adjacent the protrusion portion and a lower electrode electrically connected to the phase-changeable material pattern. According to one aspect of the present invention, an oxidation barrier layer may cover an area where a sidewall of the phase-changeable material pattern and a sidewall of the protrusion portion adjoin. More stable operation and a longer operational lifetime of the phase-change memory device are some of the benefits of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 a is a schematic view of an embodiment that features a phase-change memory cell array (CA) and a peripheral circuit area (PCA) of the present invention.

FIG. 1 b is a plan view of a portion of a phase-change memory cell array area and peripheral circuit area according to an embodiment of the present invention.

FIGS. 2-9 are each cross-sectional views taken along line I-I′ of FIG. 1 b showing processing steps of manufacturing an embodiment of the invention.

FIG. 10 is a sectional view illustrating a unit cell of a phase-change memory device according to another embodiment of the present invention.

FIG. 11 is a sectional view illustrating a unit cell of a phase-change memory device according to still another embodiment of the present invention.

FIG. 12 is a sectional view illustrating a unit cell of a phase-change memory device according to yet another embodiment of the present invention.

FIG. 13 is a schematic block diagram of a portable electronic apparatus adopting an embodiment of a phase-change memory device of the invention.

FIG. 14 is a graph showing the lower electrode contact resistance characteristic between a phase-changeable material and a lower electrode of the phase-change resistors manufactured according to embodiments of the present invention.

FIG. 15 is a graph showing programming characteristic of a conventional phase-change memory device without an oxidation barrier layer.

FIG. 16 is a graph showing programming characteristic of a phase-change memory device of an embodiment of the invention with an oxidation barrier layer.

FIG. 17 is a graph illustrating set/reset resistance characteristics of the phase-change memory cells fabricated according to the present invention and the conventional art.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 a is a schematic view of an embodiment that features a phase-change memory cell array CA and a peripheral circuit area PCA of the present invention. The cell array area CA comprises an array of memory cells CL each of which in turn comprises an access transistor TA and a phase-change resistor RP. Each memory cell CL is connected to a bit line BL, a word line WL, and a common source line CSL in a configuration that is known in the art. Other conventional structures will be included in the present invention. For example, the peripheral circuit area PCA includes first and second integrated circuits PCA1, PCA2 to drive the memory cells CL. The state of a memory cell CL is determined by a current sensing of a writing current IW. The current sensing and other functions of memory control are known to one skilled in the art.

FIG. 1 b is a plan view of a portion of the phase-change memory cell array area CA and a portion of the peripheral circuit area PCA according to an embodiment of the invention. FIG. 1 b shows a cell active region 3 c, a common source line 27 s′ (which will be referred to as “common source pad 27 s′” in the context of subsequent figures), cell gate electrodes 7 c, a peripheral gate electrode 7 p, a bit line 57, first and second source contact holes 19 s′ and 19 s″, a bit line contact hole 55 a, first and second drain contact holes 19 d′ and 19 d″, a phase-change resistor 44 a, and a phase-change resistor contact hole 29 a. The details of these elements will be explained later.

FIGS. 2-9 are each cross-sectional views taken along line I-I′ of FIG. 1 b showing a processing step of manufacturing an embodiment of the present invention.

Referring to FIG. 2, the cell gate electrode 7 c and the peripheral gate electrode 7 p are respectively formed on a cell gate dielectric layer Sc in the cell active region 3 c and on a peripheral gate dielectric layer 5 p in a peripheral circuit active region 3 p, defined by a field isolation region 3 that is formed on a semiconductor substrate 1. The widths of the cell gate electrode 7 c and the peripheral gate electrode 7 p may be different. Preferably, the width of the peripheral gate electrode 7 p is at least about 1.5 times greater than that of the cell gate electrode 7 c. Furthermore, the peripheral gate dielectric layer 5 p may be formed to be thicker than the cell gate dielectric layer 5 c.

Referring to FIG. 3, a peripheral circuit MOS transistor TP and a cell access MOS transistor TA are formed. In detail, using the cell gate electrode 7 c as an ion implantation mask, an n-type first low concentration impurity region 9 a is formed in the cell active region 3 c. Further, a p-type second low concentration impurity region 9 b is formed in the peripheral circuit active region 3 p, using the peripheral gate electrode 7 p as an ion implantation mask.

Also, a gate spacer 11 of a conventional spacer material such as oxide or nitride is preferably formed along opposite sides of the cell gate electrode 7 c and also along opposite sides of the peripheral gate electrode 7 p, using conventional techniques.

Next, using the gate spacer 11, an n-type first source region 13 s′ and an n-type first drain region 13 d′ are formed in the cell active region 3 c. In addition, a p-type second source region 13 s″, a p-type second drain region 13 d″ are subsequently formed in the peripheral circuit active region 3 p, using the methods known in the art. As a result, a pair of access (switching) MOS transistor TA are formed in the cell area CA and a peripheral MOS transistor TP is formed in the peripheral circuit area PCA.

A silicide layer 15 b may be formed on at least one of the second source and drain regions 13 s″ and 13 d″ and the peripheral gate electrode 7 p. A silicide layer 15 a may be formed on at least one of the first source and drain regions 13 s′ and 13 d′ and the cell gate electrode 7 c. Then, a lower etch stopper 17 is formed over the resulting structure.

Referring to FIG. 4, a lower insulating layer 19 is formed over the lower etch stopper 17, both of which are combined to form a lower inter-level insulating layer 20.

Subsequently, the first source contact hole 19 s′, the first drain contact hole 19 d′ are formed in the lower inter-level insulating layer 20 in the cell area CA. Then, a first source contact plug 21 s′ and a first drain contact plug 21 d′ are respectively formed in the first source contact hole 19 s′, the first drain contact hole 19 d′, using the methods known in the art. Also, the second source contact hole 19 s″, the second drain contact hole 19 d″, a second source contact plug 21 s″, and a second drain contact plug 21 d″ are formed in the peripheral circuit area PCA in the lower inter-level insulating layer 20, using the conventional techniques.

Then, an upper inter-level insulating layer 26 is formed, comprising an upper etch stopper 23 and an upper insulating layer 25. An element 28 denotes an interlayer insulating layer comprised of the layers 17, 19, 23, and 25 described above.

Referring to FIG. 5, a common source pad 27 s′, which represents a cross-section of the common source line 27 s′ in FIG. 1 b, a conductive pad, i.e., a first drain pad 27 d′, a peripheral circuit region source pad 27 s″, and a peripheral circuit region drain pad 27 d″ are formed within the upper inter-level insulating layer 26 shown in FIG. 4. These elements are formed according to processes known to one skilled in the art. Consequently, the common source pad 27 s′ and the first drain pad 27 d′ are respectively electrically connected to the first source region 13 s′ and the first drain region 13 d′.

Afterwards, a molding layer 29 is formed on the resulting structure. A phase-change resistor contact hole 29 a is then formed in the molding layer 29, using photolithography and etching processes. The molding layer 29 is preferably formed of a material having a high thermal conductivity. For example, the molding layer 29 has a thermal conductivity higher than that of silicon oxide. This gives a high rapid quenching efficiency of a phase transition of a phase-changeable material pattern, in addition to an oxygen barrier characteristic to prevent the phase-changeable material pattern from being oxidized. Such materials include silicon nitride and silicon oxynitride, for example.

Turning to FIG. 6, a conformal contact spacer layer 34 may be formed of either one or two layers. Preferably, the conformal contact spacer layer 34 is formed under vacuum without using an oxygen gas. If the oxygen gas is used to form the conformal contact spacer layer 34, to prevent the oxidation of the drain pad 27 d, it is preferable to use a lower formation temperature. The conformal contact spacer layer 34 may be a silicon nitride layer formed using plasma-enhanced (PE) CVD, or low-pressure (LP) CVD. The conformal contact spacer layer 34 may be formed of two layers, comprising a lower contact spacer layer 31 of a silicon oxynitride layer formed by using PE-CVD at less than about 500° C., and an upper contact spacer layer 33 of silicon nitride formed by using LP-CVD at greater than about 500° C.

Referring to FIG. 7, the conformal contact spacer layer 34 is anisotropically etched to expose the first drain pad 27 d′. As a result, a contact spacer 34 a including an inner contact spacer 31 a and an outer contact spacer 33 a, is formed. The outer contact spacer 33 a surrounds an outer wall of the inner contact spacer 31 a.

Then, a lower electrode 35 is formed in the phase-change resistor contact hole 29 a within the contact spacer 34 a. However, depending on the application, the contact spacer 34 a may not be necessary. The lower electrode 35 is electrically connected to the first drain pad 27′, which is in turn electrically connected to the first drain region 13 d′ of the switching transistor TA through first contact plug 21 d′. In detail, the lower electrode 35 in the phase-change resistor contact hole 29 a may be formed by depositing a conductive film such as a TiN film, or a TiAlN film overlying the molding layer 29 and within the contact hole 29 a and by planarizing the conductive film until the molding layer 29 is exposed. As a result, the contact spacer 34 a surrounds the sidewall of the lower electrode 35.

Subsequently, a phase-changeable material layer 37, an upper electrode layer 39, a glue layer 41, and a hard mask layer 43 are sequentially formed on the resulting structure including the molding layer 29. The hard mask layer 43 may be formed of SiO₂. The glue layer 41 may be a wetting layer such as SiN. One skilled in the art will, however, understand that the above-described structure is only a preferred embodiment and other suitable structures can also be used within the spirit and scope of the present invention. For example, the hard mask layer 43 can be formed using a dielectric material other than SiO₂.

The phase-changeable material layer 37 may be formed of a chalcogenide material, including, but not limited to, a GeSbTe alloy, or a Si or N doped GeSbTe alloy, with a thickness of, for example, about 1000 Å.

In FIG. 8, a phase-change resistor 44 a may be formed by patterning the hard mask layer 43, the glue layer 41, the upper electrode layer 39, and the phase-changeable material layer 37 to form a hard mask layer pattern 43 a, an upper electrode 39 a, and a phase-changeable material pattern 37 a, and then etching an upper portion of the molding layer 29 to thereby be completely separated from an adjacent phase-changeable material pattern 37 a. This process also creates a protrusion portion 77 of the molding layer 29 that is self-aligned with the phase-change resistor 44 a. The protrusion portion 77 of the molding layer 29 results in a surface step difference indicated by symbol “S,” shown in FIG. 8. The phase-changeable material pattern 37 a is electrically connected to the lower electrode 35.

Next, an oxidation barrier layer 48 may cover the resulting structure including the phase-change resistor 44 a. The oxidation barrier layer 48 may comprise a single layer of nitride, for example, silicon nitride or silicon oxynitride, deposited using a PE-CVD process, or an atomic layer deposition (ALD) process at less than or equal to about 350° C. Alternatively, the oxidation barrier layer 48 may be formed of double layers, comprising a lower oxidation barrier layer 45 of nitride, such as silicon nitride or silicon oxynitride, deposited using a PE-CVD process or an ALD process at less than or equal to about 350° C.; and an upper oxidation barrier layer 47 of nitride, such as silicon nitride or silicon oxynitride, deposited using PE-CVD process or an LP CVD process at higher than or equal to about 350° C.

The oxidation barrier layer 48 prevents the phase-changeable material pattern 37 a from being oxidized or contaminated by oxygen or impurities that may penetrate into an interface between the lower electrode 35 and the phase-changeable material pattern 37 a, or another interface between the upper electrode 39 a and the phase-changeable material pattern 37 a during a process such as an oxide deposition (ILD deposition) to cover the phase-change resistor 44 a.

Because the oxidation barrier layer 48 covers the sidewalls of the protrusion portion 77 of the molding layer 29, as well as the sidewalls and/or the upper surface of the phase-change resistor 44 a, penetration of oxygen into the phase-change resistor 44 a can be efficiently blocked.

Additionally, a plasma nitridation process may be performed on the surface of the phase-change resistor 44 a, using an N₂ or NH₃ gas at less than or equal to about 350° C. before forming the oxidation barrier layer 48.

Still referring to FIGS. 1B and 8, according to another aspect of the present invention, the oxidation barrier layer 48 may be formed by sequentially stacking a lower oxidation barrier layer 45, a stress buffer layer 46, and an upper oxidation barrier layer 47. The lower oxidation barrier layer 45 may be formed of a nitride layer such as a silicon oxynitride layer or a silicon nitride layer. The upper oxidation barrier layer 47 may be formed of a nitride layer such as a silicon oxynitride layer or a silicon nitride layer, or a metal oxide layer such as an aluminum oxide layer (AlO), a titanium oxide layer (TiO), a zirconium oxide layer (ZrO), a hafnium oxide layer (HfO), or a lanthanum oxide layer (LaO). Further, the stress buffer layer 46 may be formed of a material layer for alleviating the stress applied to the lower oxidation barrier layer 45 due to the presence of the upper oxidation barrier layer 47. For example, the stress buffer layer 46 may be formed of a silicon oxide layer using a plasma CVD technique at a temperature of about 200 to about 400° C.

If the lower oxidation barrier layer 45 is formed at a temperature lower than 350° C. as described above, the lower oxidation barrier layer 45 may be porous. In this case, since an oxygen blocking efficiency of the lower oxidation barrier layer 45 may be lowered, the lower oxidation barrier layer 45 is preferably densified. The densification process may be performed using an annealing technique or a plasma treatment technique. The annealing process may be performed using a nitrogen gas or an ammonia gas as an ambient gas at a temperature of about 400° C., and the plasma treatment process may be performed using a nitrogen gas or an ammonia gas as a plasma source gas at a temperature of about 200 to about 400° C.

The upper oxidation barrier layer 47 may not be in direct contact with the phase-change material layer patterns 37 a. Thus, the upper oxidation barrier layer 47 may be formed in consideration of an oxygen blocking performance rather than damage applied to the phase-change material layer patterns 37 a. That is, the upper oxidation barrier layer 47 may be formed at a temperature higher than a temperature at which the lower oxidation barrier layer 45 is formed. For example, the upper oxidation barrier layer 47 may be formed using a plasma CVD technique, a low pressure CVD technique or an atomic layer deposition technique at a temperature higher than about 350° C.

In an embodiment of the present invention, the upper oxidation barrier layer 47 may be formed of an aluminum oxide layer using an atomic layer deposition technique. In this case, the aluminum oxide layer is formed using an ozone gas. The ozone gas has a stronger corrosive property than an oxygen gas. Nevertheless, since the phase-change material layer patterns 37 a are covered with the lower oxidation barrier layer 45, the damage applied to the phase-change material layer patterns 37 a during formation of the upper oxidation barrier layer 47 can be minimized.

In another embodiment of the present invention, a metal oxide layer used as the upper oxidation barrier layer 47 may be formed using a sputtering technique. In this case, the metal oxide layer may be formed by depositing a metal layer using the sputtering technique and oxidizing the metal layer. For example, in the event that the upper oxidation barrier layer 47 is formed of an aluminum oxide layer, the aluminum oxide layer may be formed by depositing an aluminum layer using a sputtering technique and oxidizing the aluminum layer. When the aluminum oxide layer is formed using a sputtering technique and an oxidation process as described above, the aluminum oxide layer may be formed to have a final thickness corresponding to one and half times that of the aluminum layer formed by the sputtering process. For example, if a final target thickness of the aluminum oxide layer employed as the upper oxidation barrier layer 47 is 150 Å, the aluminum oxide layer can be formed by depositing an aluminum layer with a thickness of 100 Å using a sputtering technique and oxidizing the aluminum layer.

The lower oxidation barrier layer 45 may be formed to a thickness of 200 to 1000 Å, and the upper oxidation barrier layer 47 may be formed to a thickness of 10 to 150 Å. Preferably, the lower oxidation barrier layer 45 may be formed to a thickness of 300 to 500 Å, and the upper oxidation barrier layer 47 may be formed to a thickness of 50 to 100 Å.

Other embodiments may omit at least one of the densification process of the lower oxidation barrier layer 45, the formation process of the stress buffer layer 46 and the formation process of the upper oxidation barrier layer 47.

FIG. 9 shows the structure of FIG. 8 with the addition of a lower inter-metal dielectric (IMD) 49, an upper electrode contact hole 49 a, an upper peripheral source pad contact hole 49 s″, an upper peripheral drain pad contact hole 49 d″, an upper electrode contact plug 51, a peripheral upper source plug 51 s″, a peripheral upper drain plug 51 d″, a bit line pad 53, a source metal line 53 s″, a drain metal line 53 d″, an upper IMD 55, a bit line contact hole 55 a, and a bit line 57. These additional elements are added according to processes known to those familiar in the art.

Next, a passivation layer 62 including a silicon oxide layer 59 and a silicon nitride layer 61 is formed on the resulting structure to complete a phase-change memory device having the oxidation barrier layer 48.

Consequently, the resulting memory device includes a molding layer 29 overlying a semiconductor substrate 1. The molding layer 29 has a protrusion portion 77 vertically extending from a top surface 67 of the molding layer 29. The protrusion portion 77 may have a thickness of at least 100 angstroms, preferably, in a range of about 300 to about 600 angstroms.

The memory device further includes a phase-changeable material pattern 37 a adjacent to the protrusion portion 77 and a lower electrode 35 electrically connected to the phase-changeable material pattern 37 a. The lower electrode 35 may extend through the protrusion portion 77, preferably along a center portion thereof. The protrusion portion 77 may be located above the first drain pad, i.e., conductive pad 27 d′. Further, the phase-changeable material pattern 37 a may overlie the protrusion portion 77, although other configurations are also possible as long as the phase-changeable material pattern 37 a is adjacent the protrusion portion 77 within the spirit and scope of the present invention. Also, a sidewall of the phase-changeable material pattern 37 a may be self-aligned with a sidewall of the protrusion portion 77. The phase-changeable material pattern 37 a preferably comprises a chalcogenide material such as a GST (GeSbTe) alloy. According to an aspect of the present invention, the GST alloy may be doped by at least one of silicon and nitrogen.

The device may further include an upper electrode 39 a electrically connected to the phase-changeable material pattern 37 a.

Also, the device may include an oxidation barrier layer 48 covering at least a portion of a sidewall of the phase-changeable material pattern 37 a and at least a portion of a sidewall of the protrusion portion 77. In one aspect, the oxidation barrier layer 48 may cover the phase-changeable material pattern 37 a and the upper electrode 39 a. More particularly, the oxidation barrier layer 48 preferably covers an area where a sidewall of the phase-changeable material pattern 37 a and a sidewall of the protrusion portion 77 adjoin such that penetration of oxygen into the phase-change resistor 44 a can be efficiently blocked. Consequently, with the embodiments of the present invention, a more reliable phase-change memory device can be formed in the present invention.

In another aspect of the present invention, the oxidation barrier layer 48 may comprise a first portion overlying a top of the upper electrode 39 a and a second portion covering a sidewall of the phase-change layer pattern 37 a. Although not illustrated in the drawing, the first portion has a thickness greater than the thickness of the second portion. Preferably, the thickness of the second portion is greater than or equal to about 300 angstroms.

FIG. 10 is a sectional view illustrating methods of fabricating a unit cell of a phase-change memory device according to another embodiment of the present invention. This embodiment is only different from the embodiment illustrated in FIG. 8 for the method of forming the lower oxidation barrier layer, which corresponds to the element 45 of FIG. 8. Therefore, only the method of forming the lower oxidation barrier layer will be described in this embodiment for simplicity.

Referring to FIG. 10, phase-change resistors 44 a are formed over a semiconductor substrate 1 using the same method as described with reference to FIGS. 2 to 8. A lower oxidation barrier layer 45 is formed on the substrate 1 having the phase-change resistors 44 a using substantially the same method as described with reference to FIG. 8. The lower oxidation barrier layer 45 is anisotropically etched, thereby forming lower oxidation barrier layer patterns 45 a having a spacer shape on the sidewalls of the phase-change resistors 44 a and on the sidewalls of the protrusions 77. The spacer-shaped lower oxidation barrier layer patterns 45 a may be densified using an annealing process or a plasma treatment process as described with reference to FIG. 8. In addition, a stress buffer layer 46 and an upper oxidation barrier layer 47 may be sequentially formed on the spacer-shaped lower oxidation barrier layer patterns 45 a. As a result, the spacer-shaped lower oxidation barrier layer patterns 45 a, the stress buffer layer 46, and the upper oxidation barrier layer 47 may constitute an oxidation barrier layer 48 a.

In this embodiment, at least one of the densification process of the lower oxidation barrier layer patterns 45 a, the formation process of the stress buffer layer 46, and the formation process of the upper oxidation barrier layer 47 may also be omitted.

FIG. 11 is a sectional view illustrating methods of fabricating a unit cell of a phase-change memory device according to still another embodiment of the present invention. This embodiment is different from the embodiment illustrated in FIGS. 7 and 8 in the method of forming the phase-change material layer patterns.

Referring to FIG. 11, a molding layer 29 and a contact spacer layer 34 are formed over a semiconductor substrate 1, using substantially the same method as the embodiments described with reference to FIGS. 2 to 6. The contact spacer layer 34 is anisotropically etched to form contact spacers 34 a, if the contact spacers 34 a are necessary. Then, a phase-change material layer 37 and an upper electrode layer 39 may be sequentially formed on the resulting structure having the contact spacers 34 a without forming the lower electrodes 35 shown in FIG. 7. Then, phase-change resistors 44 b and an oxidation barrier layer 48 may be formed using substantially the same methods as described with reference to FIGS. 7 and 8. As a result, each of the phase-change resistors 44 b is formed to have a phase-change material layer pattern 37 b directly contacting the conductive drain pad 27 d′ through the phase-change resistor contact hole 29 a surrounded by the contact spacers 34 a as shown in FIG. 11. That is, confined phase-change memory cells, i.e., the phase-change memory cells confined by the contact spacer 34 a, may be formed. Consequently, the phase-change material layer pattern 37 b penetrates the protrusion portion 77 (refer to FIG. 9). In this case, the conductive drain pad 27 d′ may function as a lower electrode of the phase-change resistor 44 b.

FIG. 12 is a sectional view illustrating methods of fabricating a unit cell of a phase-change memory device according to still another embodiment of the present invention. This embodiment is a combination of the embodiments shown in FIGS. 10 and 11.

Referring to FIG. 12, confined phase-change resistors 44 b are formed over a semiconductor substrate 1 using substantially the same method as described with reference to FIG. 1. An oxidation barrier layer 48 a is formed on the substrate 1 having the confined phase-change resistors 44 b using substantially the same methods as described with reference to FIG. 10.

FIG. 13 shows a typical application of an embodiment of the invention. A portable electronic apparatus 600, such as a cell phone, utilizes a phase-change memory device 602 in conjunction with a processor 604 and an input/output device 606.

FIG. 14 is a plot showing a distribution of contact resistances for four samples, A, B, C, and D shown in Table 1 below.

Prior art Some of the examples of the present invention process parameter sample A sample B sample C sample D molding layer silicon oxynitride (SiON) outer contact spacer silicon oxynitride (SiON; plasma CVD) Inner contact spacer silicon nitride (SiN; LP CVD) lower electrode titanium nitride (TiN), diammeter: 50 nm) phase-change material GeSbTe alloy upper electrode titanium (TiN) oxidation barrier None SiON layer SiN layer 200° C., lower SiN layer (200° C., PECVD, 200 Å) (200° C., PECVD, 200 Å) PECVD, 200 Å) upper SiN layer (400° C., PECVD, 200 Å)

Sample A does not include an oxidation barrier layer, in contrast with the embodiments of the present invention. In FIG. 14 it is easy to see that the contact resistance for sample A has a much greater distribution than those of samples B, C, and D, each of which includes an oxidation barrier of various embodiments of the present invention.

Specifically, sample B comprises a SiON layer, sample C comprises an SiN layer, and sample D comprises a lower and an upper oxidation barrier layer, each of SiN. For sample B, the SiON layer is formed using a PECVD process at 200° C., to a thickness of 200 Å. For sample C, the SiN layer is formed the same way as for sample B. For sample D, both SiN layers are formed as for samples B and C, except the upper layer is processed at 400° C.

FIG. 14 demonstrates the improvement over the conventional art, e.g., sample A, with the lower electrode contact resistances of phase-change resistors of samples B, C, and D showing very uniform distribution characteristics. The sample D among the samples manufactured by the invention has the most stable distribution characteristic.

FIG. 15 is a graph showing programming characteristics of a conventional phase-change memory device without an oxidation barrier layer.

Up to about 5,000 programming cycles, a conventional phase-change memory device has a very low reset resistance value of 6,000-100,000 Ω, as compared with a set resistance value. Thus it is difficult to get enough sensing margin to read the memory cell information accurately.

FIG. 16 is a graph showing programming characteristic of a phase-change memory device of an embodiment of the present invention with an oxidation barrier layer. After 10 programming cycles, the phase-change memory device according to an embodiment of the invention has a very high reset resistance value of 30,000-3,000,000 Ω as compared with a set resistance value. Thus it has a very high sensing margin.

Comparing FIGS. 15 and 16, one can see that the interface region acting as a programming region of a phase-changeable material layer pattern of the present invention with an oxidation barrier layer has a better quality than that of a conventional phase-changeable material layer pattern.

EXAMPLES

FIG. 17 is a graph illustrating set/reset resistance characteristics of the phase-change memory cells fabricated according to the present invention and the conventional art. In FIG. 17, a horizontal axis represents a diameter D of the phase-change material patterns, and a vertical axis represents a resistance R of the phase-change resistors. In the graph of FIG. 17, the data indicated by reference letters “NR” and “NS” represent a reset resistance and a set resistance of the conventional phase-change resistors fabricated without an oxidation barrier layer, respectively. The data indicated by reference letters “SR” and “SS” represent a reset resistance and a set resistance of the phase-change resistors covered with a single oxidation barrier layer, respectively. Further, the data indicated by reference letters “DR” and “DS” represent a reset resistance and a set resistance of the phase-change resistors covered with a double oxidation barrier layer, respectively. The phase-change resistors exhibiting the measurement results of FIG. 17 were fabricated using the process conditions listed in the following Table 2.

TABLE 2 Present invention Conventional single barrier double barrier Process parameters art layer layer molding layer silicon oxynitride layer (SiON) lower electrode titanium nitride layer (TiN), diameter (50 nm) phase-change GST alloy layer (GeSbTe alloy layer) material layer upper electrode titanium nitride layer (TiN) oxidation barrier None SiN layer, lower barrier layer 500 {acute over (Å)}, layer (SiN layer, PECVD 500 {acute over (Å)}, PECVD) upper barrier layer (AlO layer, 50 {acute over (Å)}, ALD)

Referring to FIG. 17 and Table 2, a difference between a set resistance and a reset resistance of the conventional phase-change resistors was gradually reduced with a reduction of the diameter D of the phase-change material pattern. For example, when the diameter D of the phase-change material pattern was reduced from 0.68 μm to 0.4 μm, a reset/set resistance ratio of the conventional phase-change resistors is abruptly reduced from about 1.6×10² to about 0.5×10. Further, the conventional phase-change resistor having the phase-change material pattern with a diameter of 0.4 μm exhibited a non-uniform set resistance of about 6×10⁴ Ω to about 7×10⁵ Ω.

On the other hand, a reset/set resistance ratio of the phase-change resistors covered with a single oxidation barrier layer was decreased from about 1.6×10² to about 1×10², when the diameter D of the phase-change material pattern was reduced from 0.68 μm to 0.4 μm. Further, a reset/set resistance ratio of the phase-change resistors covered with a double oxidation barrier layer was decreased from about 2.5'10² to about 1.3×10², when the diameter D of the phase-change material pattern was reduced from 0.68 μm to 0.4 μm. Particularly, the phase-change resistors covered with a single oxidation barrier layer or a double oxidation barrier layer and having the phase-change material pattern with a diameter of 0.4 μm exhibited a more uniform set resistance compared to the conventional phase-change resistors having the phase-change material pattern with a diameter of 0.4 μm.

Although the invention has been described with reference to the preferred embodiments thereof, it will be understood that the invention is not limited to the details thereof. Various substitutions and modifications have been suggested in the foregoing description, and other will occur to those of ordinary skill in the art. Therefore, all such substitutions and modifications are intended to be embraced within the scope of the invention as defined in the appended claims. 

1. A semiconductor memory device comprising: a molding layer disposed over a semiconductor substrate, the molding layer having a protrusion portion vertically extending from a top surface of the molding layer; a phase-changeable material pattern having a portion overlying the protrusion portion, the phase-change material pattern having another portion penetrating the protrusion portion; and an oxidation barrier layer covering the phase-changeable material pattern and the protrusion portion.
 2. The device of claim 1, wherein the oxidation barrier layer comprises a spacer-shaped lower oxidation barrier layer that covers a sidewall of the phase-change material pattern and a sidewall of the protrusion portion, an upper oxidation barrier layer, and a stress buffer layer disposed therebetween.
 3. The device of claim 1, further comprising a contact spacer surrounding another portion of the phase-changeable material pattern. 